Biomarker for Barrett&#39;s Oesophagus

ABSTRACT

The present invention relates to the use of TFF3 in the diagnosis and detection of Barrett&#39;s esophagus using non-invasive, non-endoscopic methods.

RELATED APPLICATIONS

The present application claims the benefit of priority to British Patent Application No. 0920014.8, which was filed on Nov. 13, 2009. The entire text of the aforementioned application is incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

The present invention relates to the diagnostic methods and compositions for use in the same. More particularly, the invention related to the use of TFF3 in the diagnosis and detection of Barrett's Oesophagus using non-invasive, non-endoscopic methods.

BACKGROUND OF THE INVENTION

Oesophageal adenocarcinoma is increasing rapidly in western countries [1, 2] and patients usually present late with locally advanced disease leading to a dismal overall 5 year survival rate of 13% [3]. Barrett's oesophagus (BE), as defined by intestinal metaplasia, is the major identified risk factor for this cancer[4] and in those patients with oesophageal adenocarcinoma at presentation 90% have evidence of BE following shrinkage of the tumor post-chemotherapy[5]. However, because the majority (86%) of adenocarcinomas present de novo [6] (without prior diagnosis of BE) it is likely that a large number of BE patients remain undiagnosed in the population. This idea is supported by the high prevalence of BE (7-25% for segments of any length and 0.7-7% for long segment Barrett's) in asymptomatic patients who agreed to have a screening upper GI endoscopy when attending for colonoscopy in the US [7-9]. In keeping with these overall figures the prevalence of BE of any length was reported to be between 1 and 8% in all corners to endoscopy (reviewed in Pera, 2003 [10]). The only population prevalence data available suggests that BE is present in 1.6% of the general Swedish population [11].

Evidence from non-randomized retrospective studies demonstrated an improvement in 5-year actuarial survival from 13-43% to 62-100% in patients with surveillance-detected oesophageal adenocarcinomas[12-18]. These data suggest a potential benefit for early detection although lead time bias needs to be accounted for. Rapid advances in endoscopic technologies (reviewed by Reddymasu and Sharma [19]) as well as the development of chemoprevention strategies[20, 21] afford the opportunity to improve patients' outcomes if disease is detected early.

Thus, identification of undiagnosed BE patients should ultimately reduce mortality from oesophageal adenocarcinoma. To attain this objective, population-based screening for Barrett's is required. However there are major feasibility and cost implications for the wide-scale application of screening using the gold standard endoscopy [22].

Since the architecture of the tissue is well conserved, H&E slides may be reviewed by an expert gastrointestinal histopathologist but morphology alone is often not sufficient to diagnose BE and is open to subjectivity.

Novel screening strategies might include symptom nomograms, wireless capsule endoscopy and balloon cytology[23-25] but these have not yet been demonstrated to be sufficiently sensitive and specific for clinical use [26-28]. Recently, a study using a wireless video capsule attached to a string, allowed a more careful examination of the oesophagus and eliminated previous a major imaging drawback of fast oesophageal transit time with a reported sensitivity of 93.5% [29]. However, this approach does not permit a pathological diagnosis or the potential for implementing risk stratification using biomarkers.

Neither the British Society of Gastroenterology nor the American Gastroenterology Association currently recommend endoscopic screening for BE [22, 57] (recommendations grade C and B respectively, both based on cohort and case control studies). However, both professional organizations agree that surveillance is in order once BE is diagnosed. However, for surveillance to be of use, all Barrett's patients, symptomatic or asymptomatic would need to be diagnosed. This suggests population screening for BE may be recommended if a cost effective test could be developed. It is a problem that there is currently no suitable cost effective test available. The present invention seeks to overcome problem(s) in the art.

BRIEF SUMMARY OF THE INVENTION

The present invention relates to the use of TFF3 in the diagnosis and detection of Barrett's Oesophagus using non-invasive, non-endoscopic methods. In particular, the methods of the present invention relate to screening for Barrett's oesophagus (BE) in a subject comprising obtaining a sample of cells from the cellular surface of the oesophagus of a subject, determining the presence of Trefoil factor 3 (TFF3) in said sample of cells, wherein the presence of said TFF3 is indicative of said subject having BE. In particular embodiments, this non-invasive screening method employs cells taken from the subject wherein the cells are a mixed population of cells taken from the cellular surface of the oesophagus. More specifically, the oesophageal cells comprise cells from the oesophagus and gastric mucosa cells. It is a particular feature of the present invention that the method does not require the use of an endoscopy or other biopsy but is instead a non-invasive sampling method that simply uses the cells from an oesophageal brushing, preferably a non-endoscopic oesophageal brushing. Moreover, it is an advantage of the present invention that the screening method can be performed and yield positive results even in the absence of the subject having BE lesions.

In the methods described herein the cells are collected in a non-invasive manner using a swallowable device comprising an abrasive material capable of collecting cells from the surface of the oesophagus. For example, such a device comprises a capsule sponge that can be scraped along the oesophageal tract and withdrawn and the cells deposited thereon analysed for the presence of TFF3 protein or expression of TFF3. The methods described herein have a superior specificity and sensitivity as compared to the methods known in the art. For example, use of the TFF3 as a diagnostic marker for diagnosis of BE produces at least about high specificity of 80% and about 65% respectively. More particularly, the method has a specificity and sensitivity for diagnosis of BE of about 94% and about 78% respectively.

The methods of the invention may further be used to differentiate a mixed population of alimentary tract cells obtained from a subject suspected of having Barrett's oesophagus (BE) comprising determining the presence or expression of TFF3 on the surface of said cells, wherein the presence of TFF3 on the surface of any of the cells in the mixed population of cells identifies said cells as being from a BE lesion in the alimentary tract.

The TFF3 may be detected using any method known in the art. Advantageously, the presence of TFF3 is detected in an immunoassay using an antibody specific for TFF3. In other embodiments, the TFF3 is detected on the surface of the cells using an immunohistochemical detection method. The diagnosis of BE may be further confirmed by staining the cells with an Alcian Blue stain which is known to stain positive for cells taken from BE lesions.

BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWINGS

FIG. 1: Venn diagram of the number genes identified by analyses 1, 2 and genes common to the two microarray analyses. Analysis 1 and 2 yielded 24 and 93 putative targets respectively. A total of 14 genes common to both analyses were validated further. (BE: Barrett's oesophagus, NE: normal oesophagus, NS: normal stomach, CG: chronic gastritis, GIM: gastric intestinal metaplasia).

FIG. 2: mRNA expression of the putative genes identified. The Y axis represents the −ΔCt (defined as −(Ct_(target)−Ct_(GAPDH))). The stars indicate statistical significance by one-way ANOVA (* p=0.0339 and ** p=0.0012); only genes whose expression was significantly increased in BE compared to NE and GM are marked on this graph. In both cases, the genes were statistically upregulated in BE compared to NE and GC. In addition, AGR2, ATP7B, FBP1, FMO5, FOXA3, GOLPH2, LYZ, RNAase4 and TFF1 are statistically upregulated in BE (Barrett's oesophagus) and GC (gastric cardia) compared to NE (normal oesophagus).

FIG. 3: Immunohistochemistry for TFF3 and DDC. Representative immunohistochemistry (×100) of TFF3 in the positive control duodenum, NE (normal oesophagus), BE (Barrett's oesophagus), GM (gastric mucosa).

FIG. 4: Cumulative score for TFF3 in normal oesophagus, Barrett's oesophagus, stomach and duodenum. TFF3 is statistically over-expressed in BE (Barrett's oesophagus) compared to NE (normal oesophagus) and GM (gastric mucosa, p<0.0001).

FIG. 5: Expression of DDC in prostate cancer, used as positive control, and in a positive Barrett's oesophagus biopsy (×100 and ×400 magnification).

FIG. 6: Representative haematoxilin and eosin and TFF3 staining of a capsule specimen collected from a Barrett's patients (×100 and ×400 magnification). The black arrow indicates the typical circular appearance of TFF3 positivity and the red arrow indicates secreted TFF3 at the apical border of the Barrett's cells.

FIG. 7 shows: Cytosponge within the capsule and expanded (A) and representative picture of positive TFF3 staining in a sample from a patient with BE (B).

FIG. 8 shows a diagram.

FIG. 9 shows a timeline.

FIG. 10 shows a summary chart.

DETAILED DESCRIPTION OF THE INVENTION

We disclose TFF3 as a biomarker for BE. We have demonstrated for the first time that microarray analysis can be directly applied to the clinic in the context of BE. TFF3 was identified as one of a number of candidate markers by selection from a large volume of publically available DNA microarray data. The inventors demonstrated that it was over-expressed in BE compared to adjacent normal tissues at the RNA and protein level. We disclose its use in a novel minimally invasive, non-endoscopic screening strategy.

The invention provides improved diagnostic accuracy via identification and validation of biomarker(s) that have the ability to clearly distinguish between cells from BE, normal gastric and squamous oesophageal cells since the preferred capsule-sponge mode of collection samples cells from the stomach to the oro-pharynx. The biomarker provided is highly specific which has the advantage of minimising cost since in a screening programme, patients with a positive capsule test would need to undergo endoscopy to verify the diagnosis and allow for multiple biopsies to be performed to exclude dysplasia.

Trefoil factors are mucin-associated peptides thought to be involved in multiple biological functions including repair of the mucosa through enhancement of restitution (mucosal repair by cell migration) and modulation of stem cells differentiation as well as interaction with mucins and modulation of the mucosal immune response [40-43]. In the gastrointestinal tract, TFF1 and 2 are mainly expressed by the gastric epithelium [42] while TFF3 is expressed by the intestine and intestinal metaplasia of the stomach and oesophagus [44, 45]. TFF3 expression has been demonstrated to be increased by gastro-oesophageal reflux disease[45], and transient overexpression of the homeodomain protein CDX2[46], linking its expression to the development of BE. Interestingly, there have been a number of publications concerning the development of novel cytological methods using TFF3 to detect thyroid follicular carcinomas [47, 48] and it has been suggested that TFF3 could also be detected in the serum of patients with high-grade endometrial carcinomas [49]. It might therefore be possible to develop a serum based assay to screen for BE using TFF3 as a marker.

Dopadecarboxylase metabolizes 3,4-dihydroxyphenylalanine (DOPA) to dopamine and 5-hydroxytryptophan to serotonin [50]. Overexpression of DDC is also a feature of a number of malignancies ranging from retinoblastomas [51, 52] to small cell lung cancers [53], prostate cancers [54] and gastric cancers with peritoneal disseminations [55]. In most of these tumor types, an effort has been made to use DDC diagnostically using PCR techniques in biopsies [54, 56] or cytological specimens [55]. DDC may therefore be of interest as a biomarker for malignant conversion in Barrett's and due to the poor immunohistochemistry staining a PCR based assay may be more applicable.

An advantage of this novel capsule sponge test is that it can be performed in primary care. Since the TFF3 analysis presented here relies on standard immunohistochemical techniques it is an objective test that would be readily applicable to clinical pathology laboratories in a cost effective manner. Furthermore, in the future other assays could be applied to these sponge samples such as PCR based assays to determine gene expression levels of multiple biomarkers or DNA based assays to determine methylation status or loss of heterozygosity. Such methodologies might increase the price of the test but may also be informative with regards to the risk of progression to cancer. The typical circumscribed appearance of TFF3 positivity and the strength of the staining make it particularly suited for automation thus potentially further reducing the cost of a screening program incorporating this methodology.

For such a BE screening test, it is advantageous to have a high specificity to avoid calling patients for unnecessary endoscopies with the inherent generation of anxiety, high costs and risks of an invasive procedure that this would entail. With TFF3 we obtained a very high specificity of 94% and an adequate sensitivity of 78%. It is unlikely for a single marker to provide both a high sensitivity and specificity. It is reasonable to accept that a device like the capsule sponge, while sampling from the entire surface of the mucosa, will only collect cells that detached. Small foci of IM, yielding TFF3 positivity, may be missed, explaining the sensitivity of 78%.

TFF3

In the search for a robust marker, the inventors undertook an intensive genetic and biochemical analysis. Initially, the inventors analysed data relating to approximately 54,000 genes. This initial screening effort was based on a combination of various available data sets. The aim was to identify candidate markers which might be increased in Barrett's oesophagus but would not show an increase in non-Barrett's tissue such as gastric cardia or squamous oesophagus. This was an impartial analysis with no bias or choice introduced in selection of candidates. In other words, this could be regarded as a genome wide search. Promising candidates were taken forward for validation.

An initial validation step was based on PCR amplification. Candidates passing this test were taken forward.

A further step towards validation was to obtain antibodies recognising the candidates. Those candidates which could be recognised by antibodies were taken forward for further validation.

A further validation step was undertaken by tissue staining. Those antibodies capable of showing a differentiation/discrimination were taken forward for further validation.

Antibody staining was then validated on samples of cells which were obtained non-specifically (for example by use of a capsule sponge sampling technique).

The culmination of the design and application of each of the rigorous screening steps devised and implemented by the inventors was the identification of TFF3 as a robust marker for Barrett's oesophagus.

The initial genetic screening approach supplied 14 candidates. The various validation steps narrowed these 14 candidates down to only 2 candidates. One of these showed only deep tissue staining together with infrequent or rare staining patterns and behaved as a very poor marker. The conclusion of the screening and multiple validation steps was that TFF3 was the only consistent and robust marker for use in detection of Barrett's oesophagus in this setting.

TFF3 showed an initial sensitivity of 79% and an initial specificity of 94%. These findings are demonstrated in the examples section.

Furthermore, although not powered to determine accuracy of the test as a primary outcome measure, when non-specific sampling techniques such as the cytosponge sampling technique were used, TFF3 demonstrated a sensitivity of 90% and a specificity of 94% for detection of Barrett's oesophagus.

It is an advantage of the invention that these levels of sensitivity and specificity are so high. Moreover, it was an unexpected finding of the inventors at such high levels of specificity would be associated with TFF3.

Suitably sensitivity is 79% or more. Suitably sensitivity is 90% or more.

Suitably specificity is 94% or more.

Sample

Suitably the sample comprises cells from the subject of interest. Suitably the sample comprises oesophagal cells from the subject of interest. Suitably the sample is non-endoscopic ie. suitably the sample is obtained without the use of an endoscope. Endoscopic sampling is an invasive technique. Furthermore, endoscopic sampling is a targeted technique where biopsies are taken at intervals along the oesophagus, or where lesions are visually identified by the operator and specifically targeted for biopsy. Suitably the invention does not involve endoscopic samples such as endoscopic biopsies.

Prior art techniques for detecting Barrett's oesophagus have typically involved a targeted sample such as an endoscopic biopsy together with a proliferation marker such as MCM2. This essentially asks the question whether, in a specifically chosen sample obtained by a skilled endoscopic operator, there are any cells which are proliferating (e.g. dys-regulated). Although this is clearly useful, it is not suitable for population screening due to the expensive, time consuming and invasive nature of the targeted endoscopic sampling.

A key principle of the invention is to provide a marker which is specific for Barrett's oesophagus. The marker is specific for Barrett's oesophagus in the sense of not naturally occurring in unrelated tissues such as normal squamous oesophagus, or gastric cardia (stomach). Thus, by providing a marker with these specific characteristics, the invention advantageously provides a marker targeted to detection of Barrett's oesophagus cells. In this way, the invention advantageously avoids the need for targeted sample collection. Thus, the invention advantageously involves samples obtained by non-targeted sample collection such as sampling the entire surface of the oesophagus rather than only targeting areas of suspected lesions (Barrett's).

Thus, suitably sample does not comprise an endoscopic biopsy.

Suitably the sample may comprise oesophical brushings or surface cells. Oesophagal brushings may be obtained using an endoscope or by other means; suitably when the sample comprises oesophagal brushings they are obtained by non-endoscopic means.

Suitably the sample may comprise cells sampled from the entire oesophagal lumen.

Suitably the sample may comprise both oesophagal and non-oesophagal cells.

Suitably the sample may comprise oesophagal cells together with gastric cardia cells.

Most suitably, the sample may comprise cells collected using a capsule sponge type sampling technique.

Especially suitable sampling techniques are described in the examples section.

Examples of suitable samples include oesophagal brushings (whether endoscopically or non-endoscopically obtained), samples obtained via balloon cytology, samples obtained via capsule sponge sampling. Most suitably, a sample comprises cells obtained via capsule sponge sampling. It can therefore be appreciated that TFF3 possesses certain properties which make it advantageous as a biomarker for Barrett's oesophagus.

Firstly, TFF3 exhibits luminal surface expression. This means that the sample to be analysed need only be collected from the surface of the oesophagal lumen. This advantageously avoids the need for a biopsy such as an endoscopic biopsy. Moreover, this advantageously avoids the need to preserve tissue architecture in the sample being analysed.

A further advantage of TFF3 is that it is able to differentiate between the oesophagal lumen and the gastric mucosa. Specifically, TFF3 is not expressed in the gastric mucosa (e.g. gastric cardia/stomach). This has a specific advantage that if cells of the gastric mucosa are included in the sample, then TFF3 is still able to function as a robust biomarker for Barrett's. This is because TFF3 is not expressed in gastric mucosa cells, and therefore no false positives occur even when the sample comprises cells of the gastric mucosa. Thus, this capacity for differentiation is another robust advantage of TFF3 in the present invention. This property is in particularly sharp contrast to other members of the TFF3 family of proteins since TFF3 appears to be unique amongst TFF proteins in not identifying cells of the gastric mucosa.

Thus it can be appreciated that the choice of TFF3 by the inventors provides a degree of specificity which has not yet been provided in any prior art approach to screening for Barrett's oesophagus. The present inventors were the first to actively seek, and to successfully provide, a marker capable of such focused discrimination. Moreover, sampling techniques in the prior art have been confined to oesophagus. Thus, the inventors are the first to have identified the utility of a marker having the properties disclosed herein, as well as being the only ones to have identified such a marker.

A non-endoscopic capsule sponge device which has been approved by the Medical Health Regulatory Agency (Ref n# CI/2007/0053) in the UK may be used for sample collection. A pilot study demonstrated that this device is acceptable to patients and could be used in primary care[30],[31]. The device consists of a polyurethane sponge, contained within a gelatin capsule, which is attached to a string. The capsule is swallowed and dissolves within the stomach after 3-5 minutes. The sponge can then be retrieved by pulling on the string. Initial studies were performed using a cell monolayer stained with a proliferation marker mcm2. This gave a suboptimal sensitivity and specificity of 67.5% and 67.4% respectively and sample heterogeneity meant that the whole sample had to be processed and analyzed for this single biomarker. More recently, we have processed the cytological specimen to a pellet which can then be embedded in paraffin thus preserving the tissue architecture. This can then undergo histological assessment and in addition, multiple immunohistochemical markers may be used on a single sample [31]. Thus, thus mode of sample collection is particularly suitable for use in the present invention.

Mode of Detection

The marker may be detected by any suitable means known in the art. For example, the marker may be detected using nucleic acid based techniques such as RNA analysis.

Suitably, the marker is detected at the protein level.

Most suitably, the marker is detected using antibodies such as anti-TFF3 antibodies.

It is an advantage of the invention that quantitative levels of expression need not be determined. It is an advantage of the invention that mere presence/absence of the marker is sufficient to aid the diagnosis of Barrett's oesophagus.

Thus it is an advantage of the invention that a qualitative measurement (e.g. simple presence or absence) is sufficient to aid the diagnosis without needing to resort to quantitative measurement.

It is an advantage of the invention that controls or reference samples are not necessary, since it is possible to work the invention scoring only a simple presence or absence of TFF3.

It is an advantage of the invention that TFF3 may be analysed on its own. In other words, combinations with other markers are not necessary for performance of the invention.

The methodology used for marker identification ensured high specificity since we identified the best discriminators between BE and NE and GM but not necessarily sensitivity because the sample size of the microarrays was not high enough. Current screening programs for prostate (prostate serum antigen), cervical (Papanicolaou test) and colon cancer (fecal occult blood test (FOBT)) have accepted sensitivities of 30-96% respectively and specificities of 77-100% respectively[59-61]. The positive predictive value of PSA for prostate cancer and of FOBT for colon cancer is 47% and 2.2-17.7% respectively [59, 60]. It may therefore be desirable to identify additional markers that, used in conjunction of TFF3, would offer a high sensitivity without loss of specificity. Naturally, if the skilled worker wishes to analyse markers other than TFF3 in parallel, then this does not adversely effect the invention. For example, it may be desired to use Alcian Blue staining in parallel with TFF3 analysis. Alcian blue stains goblet cells and typically stains the same cells as express TFF3. Alcian blue may be used to confirm Barrett's oesophagus in biopsies. Thus, in one embodiment, the invention relates to analysing a sample for the expression of TFF3, and analysing said sample using Alcian blue staining.

The invention provides non-endoscopic screening biomarkers for Barrett's oesophagus. These find application in microarray analysis and in the clinic. In particular the invention finds application in population screening such as non-invasive screening for Barrett's.

Barrett's oesophagus (BE) predisposes to oesophageal adenocarcinoma but the majority of patients are undiagnosed. A non-endoscopic cytological screening device, called a capsule sponge, makes population-based screening for BE a feasible option. However, due to the mixed cell population retrieved by the capsule sponge, biomarkers specific for BE are required. The present invention provides the TFF3 biomarker which is specific for BE, in particular specific for BE amongst the heterogeneous cells in samples such as those collected by capsule sponge sampling. In other words, TFF3 is an excellent marker for BE screening since it is expressed at the luminal surface of BE but not in adjacent tissue types and may be applied to a non-endoscopic screening device.

Further Applications

The invention may relate to use of TFF3 as a BE biomarker when used in combination with non-endoscopic sampling.

TFF3 has the advantage of luminal surface expression and differential expression with the gastric mucosa.

The invention may relate to use of TFF3 as biomarker for BE where sensitivity and specificity are at least 79% and 94% respectively. The inventors were surprised by the unexpectedly high levels of specificity and sensitivity shown for TFF3.

The present invention provides methods of aiding the diagnosis of Barrett's oesophagus or Barrett's associated dysplasia in a subject, said method comprising sampling the cellular surface of the oesophagus of said subject, and assaying the cells for the presence of TFF3, wherein detection of TFF3 indicates increased likelihood of the presence of Barrett's or Barrett's associated dysplasia. In particular, the sampling is efficient because it is not directed to a particular site within the oesophagus but instead the sample of cells is taken across the entire surface of the oesophagus. This has the advantage of avoiding more invasive sampling techniques such as biopsy collection techniques which penetrate below the surface of the oesophagus.

In addition to the detection of TFF3, the cells may also be monitored to determine the presence of other markers of BE such as those markers that are indicative of brush border proteins such as villin or moesin, mucin genes, brush border enzymes such as alkaline phosphatase, homeobox genes such as Cdx1 and/or Cdx2, cytokeratins such as CK8/18 for columnar cells, or any marker known to be differentially expressed in Barrett's versus normal oesophageal surface cells.

Preferably in addition to TFF3, the additional marker may be selected from the group consisting of proliferation markers such as Ki67 and Mcm proteins, proliferation and DNA damage markers such as PCNA, cyclins such as cyclin D and/or cyclin A, abnormal p53, loss of p16, aneuploidy or any marker known to correlate with the degree of dysplasia. More preferably the marker is Mcm2 or Cyclin A.

In the methods the invention the sampling of the cellular surface of the oesophagus comprises the steps of

(i) introducing a swallowable device comprising abrasive material capable of collecting cells from the surface of the oesophagus into the subject, (ii) retrieving said device by withdrawal through the oesophagus, and (iii) collecting the cells from the device.

Preferably step (i) comprises introducing a swallowable device comprising abrasive material capable of collecting cells from the surface of the oesophagus into the subject's stomach.

In another aspect, the invention provides a method as described above further comprising analysing the chromosomal composition of the cells, wherein detection of abnormal karyotype indicates an increased likelihood of dysplasia.

In another aspect, the invention provides a kit comprising a swallowable device comprising abrasive material capable of collecting cells from the surface of the oesophagus, together with printed instructions for its use in detection of TFF3 to diagniose Barrett's oesophagus or Barrett's associated dysplasia.

In another aspect, the invention provides a kit as described above further comprising a local anaesthetic. Preferably said local anaesthetic is a spray or lozenge, preferably a spray.

In another aspect, the invention provides a kit as described above further comprising a container for receiving said swallowable device after withdrawal, said container having a quantity of preservative fluid therein. Preferably the container is a watertight container. Preferably the preservative fluid is a cell preparation fluid. Preferably said fluid is thin preparation fluid for production of slides for examination of the sampled cells.

In another aspect, the invention provides a kit as described above wherein said device comprises a capsule sponge.

In another aspect, the invention provides a kit as described above wherein said swallowable device comprises withdrawal means such as string.

In another aspect, the invention provides a kit as described above further comprising a device for severing said withdrawal means. Preferably said device comprises a blade or scissors.

In the kit there also may be a container for administering drinkable fluid, such as water, to the subject. The kit may also contain a local anaesthetic spray or lozenge to facilitate the deliver and sampling of the oesophagus cells using the sponge device.

In another aspect, the kit invention provides a kit as described above further comprising reagents for use in the detection of at least one marker selected from the group consisting of brush border proteins such as villin or moesin, mucin genes, brush border enzymes such as alkaline phosphatase, homeobox genes such as Cdx1 and/or Cdx2, cytokeratins such as CK8/18 for columnar cells, or any marker known to be differentially expressed in Barrett's versus normal oesophageal surface cells.

Barrett's Oesophagus can occur without dysplasia. Approximately 1% of patients with Barrett's oesophagus will develop dysplasia each year. At any given time, approximately 20% of patients with Barrett's oesophagus will have dysplasia. Cancer such as adenocarcinoma develops from dysplasia and is regarded as one extreme form of dysplasia, even though pathologically the conditions clearly differ. It is desirable to obtain an early diagnosis of adenocarcinoma and the present invention is concerned with such detection and diagnosis of a single progressive disease state that has recognisable discrete stages. These stages comprise Barrett's oesophagus, Barrett's oesophagus associated dysplasia including adenocarcinoma, which arises therefrom.

In these diagnostic methods, the cells are sampled from the surface of the oesophagus using a swallowable abrasive material, which material is retrieved from the patient and from which the cells are subsequently separated for analysis to determine the presence of TFF3. Preferably substantially the entire surface of the oesophagus is sampled, preferably the entire surface. In the present invention, there is no need to focus only on Barretts oesophagus lesions as the inventors have found that the presence of TFF3 is associated only with BE and as such TFF3 can be used to specifically diagnose whether a mixed population of cells obtained from the entire surface of the oesophagus have therein cells that are from BE lesions.

By abrasive is meant that the material is capable of removing cells from the internal surface of the oesophagus. Clearly, since this is meant for use in a subject's oesophagus, ‘abrasive’ must be interpreted in the light of the application. In the context of the present invention the term ‘abrasive’ has the meaning given above, which can be tested by passing the material through the oesophagus in an appropriate amount/configuration and examining it to determine whether cells have been removed from the oesophagus.

The material used in the collection device must be sufficiently abrasive to sample any dysplastic cells present in the oesophagus. Preferably the material is sufficiently abrasive to sample any Barrett's or adenocarcinoma cells present. In a most preferred embodiment, preferably the material is sufficiently abrasive to be capable of sampling the whole oesophagus ie. so that some squamous cells are collected together with any Barrett's and/or columnar and/or adenocarcinoma cells which may be present. This is advantageous because squamous cells are more difficult to remove than dysplastic cells and so their sampling provides a control to the operator such that if normal squamous cells are removed by the material then the chances of having not sampled the cells of interest such as Barrett's or dysplastic cells (if present), which are easier to remove than normal squamous cells, is correspondingly small.

Preferably the swallowable abrasive material is expandable. In this embodiment, preferably the abrasive material is of a smaller size when swallowed than when withdrawn. An expandable material may be simply a resilient material compressed such that when released from compression it will expand again back to a size approximating its uncompressed size. Alternatively it may be a material which expands e.g. upon taking up aqueous fluid to a final size exceeding its original size.

In other words, preferably the material of the device expands, swells, inflates or otherwise increases in size between swallowing and withdrawal. Preferably the device is auto-expandable ie. does not require further intervention between swallowing and expansion. Preferably the device is not inflatable. Preferably the device expands by unfolding, unfurling, uncoiling or otherwise growing in size following removal of restraint after swallowing. Preferably the material of the device is compressible and reverts a size approximating its uncompressed size following swallowing. Preferably the device is constructed from a compressed material which is releasably restrained in a compressed state. Preferably the material is released from restraint after swallowing, allowing expansion of the device/material before withdrawal.

Preferably the device comprises compressible material which is compressed into capsule form. Preferably the compressible material is in the form of sponge material.

Preferably the compressed sponge is at least partially surrounded by a soluble and/or digestible coat such as a capsule coat. Preferably the sponge is indigestible. Preferably the capsule coat is at least partially formed from gelatin. Preferably the capsule coat is fully formed from gelatin.

In one embodiment it may be desirable to make the whole device out of digestible material to increase safety in case of a device becoming lost in the subject. Naturally the abrasive material would need to be digested at a slower rate than the capsule and the cord would need to be similarly slowly digested. Preferably the abrasive material is non-digestible. Preferably the cord is non-digestible.

Preferably the abrasive material comprises polyurethane, preferably polyurethane sponge.

Preferably the device is a capsule sponge. As will be apparent from the specification, a capsule sponge is a device comprising compressible sponge as the abrasive material, which sponge is compressed into a capsule shape, which capsule shaped compressed sponge is preferably reversibly restrained in its compressed state by at least a partial coat of soluble and/or digestible material such as gelatine. Preferably the device is a capsule sponge as supplied by Francois Venter at Medical Research Council, South Africa. Preferably the device is a capsule sponge as manufactured by Medical Wire and Equipment (MWE), Corsham, Wiltshire, UK.

Preferably the sample does not comprise endoscopically collected material. Preferably the sample does not comprise endoscopic biopsy. Preferably the sample does not comprise endoscopic brushings.

It is a feature of the invention that the sampling is not directed e.g. visually directed to any particular part of the oesophagus but rather the sponge is scraped along the entire surface of the oesophagus and obtains a heterogeneous sample of cells from the tract. It is a further advantage of the invention that a greater proportion of the surface of the oesophagus is sampled than is achieved by prior art techniques such as endoscopic biopsy (which samples approximately 1% of the surface) or endoscopic brushing. Preferably at least 10% of the oesophageal surface is sampled, preferably at least 20%, preferably at least 30%, preferably at least 40%, preferably at least 50%, preferably at least 60%, preferably at least 70%, preferably at least 80%, preferably at least 90%. In a most preferred embodiment, preferably substantially the entire oesophagus is sampled, preferably the whole inner lumen of the oesophagus is sampled. This applies equally to the in vitro sample even when the method of the invention does not include collection of the sample.

The invention will now be described by way of examples, which are intended to be illustrative and are not intended to limit the scope of the appended claims. Reference is made to the following figures.

Certain Abbreviations are used, including BE Barrett's oesophagus, CG Chronic gastritis, GC Gastric cardia, GIM Gastric intestinal metaplasia, GM Gastric mucosa, IM Intestinal metaplasia, NE Normal oesophagus, NS Normal stomach.

EXAMPLES Overview

We hypothesized that biomarkers for BE can be identified by combining and re-analyzing a number of previously published upper gastrointestinal microarray datasets. In this way we identify putative biomarkers from a combinatorial in silico analysis and then perform validation studies on independent samples at the RNA and protein level before finally applying any candidates to samples from a capsule sponge collected from an independent cohort of Barrett's patients and healthy controls.

Three publically available microarray datasets were used to identify putative biomarkers present in BE but absent from squamous oesophagus (NE) and gastric mucosa (GM). Validation was performed by QPCR (n=10 each of NE, BE, GM) and immunohistochemistry (NE n=20, BE n=21, GM n=24, duodenum n=18).

2/14 genes identified, dopa-decarboxylase (DDC) and Trefoil Factor 3 (TFF3), were confirmed by QPCR to be upregulated in BE compared to NE (p<0.01) and GM (p<0.01 and p<0.05 respectively). Immunohistochemistry confirmed that DDC protein expression was restricted to BE but was confined to <1% of the cells within the crypt compartment. TFF3 protein was expressed to high levels at the luminal surface of BE compared to absent expression in NE and GM (p<0.001).

The biomarker was then prospectively evaluated on capsule sponge specimens from 47 BE patients and 99 healthy controls. Using the capsule sponge 36/46 BE patients (1 inadequate sample) and 6/96 controls were positive for TFF3 giving a sensitivity of 78% and a specificity of 94%.

Example 1 Identification of Putative Targets

We used a strategy involving three microarray datasets to screen for candidate genes that were specifically expressed in BE. Twenty four genes from analysis 1 (Hao/Boussioutas) were found to be statistically overexpressed in BE (log₂ ratio>2) compared to NE (log₂ ratio<1) and GM (log₂<1). Using the same log₂ ratio comparisons 93 genes were identified from analysis 2 (Greenawalt/Boussioutas), (FIG. 1).

Microarray Analysis

The invention is based in part on a substantial leap forward in the translation of high throughput laboratory results into an assay that can be used in the clinic. The microarray experiments were not designed specifically to identify markers distinguishing between BE, NE and GM and to our knowledge no dataset including normal oesophagus, Barrett's oesophagus and normal gastric mucosa exists. Furthermore, the microarray platform by of Hao et al. [32] was different from the platform used by Boussioutas et al.[33] and Greenawalt et al.[34]. This explains the lower number of candidates identified in the first (Hao-Greenawalt; n=33) compared with the second analysis (Boussioutas-Greenawalt; n=111) (see below). However, very stringent statistical criteria were set to reduce the effect of these shortfalls which also reduced the number of putative targets.

A search of the literature (PubMed) and public gene expression microarray databases (GEO, Stanford Microarray Database) was performed to identify microarray datasets pertaining to gene expression patterns in IM-containing BE, NE (normal squamous oesophagus) and gastric mucosa (normal stomach (NS), chronic gastritis (CG) and gastric IM (GIM)). These tissues were selected since they will sampled by the capsule sponge.

CG and GIM were chosen to represent upper GI inflammation and Helicobacter-induced IM respectively, which may be present in the screened population and need to be distinguished from BE. Three datasets, detailed in Table 1, were selected for analysis based on the following criteria: a) data was generated from more than 5 samples per relevant tissue type and; b) the arrays used contained >10000 cDNA or oligonucleotide probes. All three microarray studies involved the hybridisation of differentially labelled test and reference cDNA to a spotted cDNA array, and data from all three studies were available in the form of normalised test:reference hybridisation signal intensity ratios. Different analyses were performed to generate a single gene list (FIG. 1). Analysis 1: Hao et al.[32] (15 NE and 14 BE) was analyzed, using a parametric test (Welch t-test) with Bonferroni correction, to identify genes which were differentially expressed between the two groups and whose expression was significantly upregulated in BE (log₂ ratio>2) compared to NE, (p<0.0001). This list was then used to interrogate Boussioutas et al. [33] (57 gastric mucosa samples (GM) comprising NS, CG and GIM) for genes that were under-expressed in GM (<1). Analysis 2: Greenawalt et al.[34] (39 NE and 26 BE) was analyzed in a similar fashion to dataset 1 to produce a set of genes with log₂ ratios BE>2, NE<1 and GM<1 (from Boussioutas et al. [33]). Data analysis was done using GeneSpring GX version 7.3 (Agilent, Palo Alto, Calif., USA). Genes common to both analyses were selected and ranked in order of statistical significance and enrichment in BE for subsequent validation.

TABLE 1 microarray datasets selected for analysis Specimens Array Reference Normalisation Source of data Hao [32] 15 Normal Spotted Commercial Intensity- Stanford microarray oesophagus cDNA human dependent database 14 Barrett's array RNA (http://genome-www5.stanford.edu) oesophagus (42,000 spots) Boussioutas 8 Normal Spotted Pool of 11 LOWESS GEO Accession [33] stomach cDNA normal normalisation GSE2669 27 Chronic array gastric gastritis (11,500 specimen 22 Gastric spots) IM Greenawalt 39 Normal Spotted Pool of 11 LOWESS ArrayExpress ID E- [34] oesophagus cDNA cell lines normalisation MEXP-692 26 Barrett's array oesophagus (11,500 spots)

It was found that 14 genes (table 3 and FIG. 1) were common to both analyses.

TABLE 3 Putative biomarkers, primer sequences and PCR conditions Accession Forward Reverse Annealing Name Symbol n# primer primer T ° C. Anterior AGR2 NM_00640 TTGTCCTCC GCAGGTT 53 gradient 2 8 TCAATCTGG CGTAAGC TTTATG ATAGAGA (SEQ ID NO. 1) C (SEQ ID NO. 2) ATPase,Cu2+ ATP7B NM_00005 ACAAAGCAC ATATTCAA 53 transporting, β 3.2 TAACCCAAA GACGCAA polypeptide GAGAC GACTTACA (SEQ ID NO. 3) ATG (SEQ ID NO. 4) Death- DAPK1 NM_00493 AACTACGAA GATCCAG 53 associated 8 TTTGAGGAT GGATGCT protein kinase-1 GAATACTTC GCAAAC (SEQ ID NO. 5) (SEQ ID NO. 6) M-Dopa DDC NM_00079 CTTCGCCTA CTTTGGTA 55 decarboxylase 0 CTTCCCCAC GTTCCAG TG (SEQ ID  CATCTTCC (SEQ ID  NO. 7) NO. 8) Fructose-1,6- FBP1 NM_00050 CACTGAGTA CTTCTTGT 57 biphosphate 7 CATCCAGAG TAGCGGG decarboxylase GAAG (SEQ ID  GTACAG (SEQ ID  NO. 9) NO. 10) Flavin FMO5 NM_00146 GGACAGGC CCTTTCAA 53 containing 1.1 GACACTAAC AGCAGAC monooxygenase AGG (SEQ ID  AGGTTCC (SEQ ID  NO. 11) NO. 12) Forkhead box FOXA3 NM_00449 TGCTGCCTC AGTGAAAT 56 A3 7.2 GACCACCAC AGGGTGT (SEQ ID  GGAGGAA NO. 13) G (SEQ ID NO. 14) Fucosyltransferase 4   FUT4 NM_00203 N/A* N/A* N/A   3.2 golgi GOLPH2 NM_17793 AGTGTGAGG TGTCTGG 53 phosphoprotein 7.1 AGCGAATAG GACTTGCT 2 AAGAG (SEQ ID  GTTACC (SEQ ID  NO. 15) NO. 16) lysozyme (renal LYZ NM_00023 GACCTAGCA CCATTCCC 53 amyloidosis) 9.1 GTCAACATG AATCTTTT AAGG  CAGAGTT (SEQ ID NO. 17) C (SEQ ID NO. 18) phospholipase PLCL2 NM_01518 CCATCAAGG ATATATGA 56 C-like 2 4.2 AAGTGAGAA CGGAAAA CAGG CGCACAA (SEQ ID NO. 19) TC (SEQ ID NO. 20) ribonuclease, RNAse4 NM_19443 GCAGAGGA CGCAGGA 57 RNase A family, 0 CCCATTCAT ATCGCTG 4 TGC (SEQ ID  GTAC (SEQ ID  NO. 21) NO. 22) Trefoil factor 1 TFF1 NM_00322 CCCCGTGAA CGTCGAT 53 5 AGACAGAAT GGTATTAG TGTG GATAGAA (SEQ ID NO. 23) GC (SEQ ID NO. 24) Trefoil factor 3 TFF3 NM_00322 TCTGGGAGC GGATTGTT 56 6.2 TTGACAAAG TGCTTGG GC (SEQ ID  GGAAGG (SEQ ID  NO. 25) NO. 26) *N/A: qPCR analysis was not performed since no suitable positive control could be identified

It is interesting to note that only 2 out of 14 targets were validated by qPCR and in most cases this was because the expression level of the putative markers was similar in GM (cardia) and BE. This suggests that the expression profile of the cardia is closer to BE than normal gastric mucosa, chronic gastritis and intestinal metaplasia of the cardia. It has previously been demonstrated that the kinome [38] and the expression profile[39] of BE have strong similarities to that of gastric cardia.

Example 2 Validation of Targets

Human Specimens

Patients undergoing upper GI endoscopy were recruited to this biomarker study from Addenbrooke's Hospital following approval by the Local Research Ethics Committee. All patients with BE, had an endoscopically visible columnar lined segment of more than 3 cm and a histopathological diagnosis of specialized intestinal metaplasia. For NE samples were taken 2 cm above the z-line in patients with BE and 2 cm above the gastro-oesophageal junction (GOJ) in patients without BE who were undergoing symptomatic evaluation as part of the routine surveillance service.

The microarray targets were validated using real-time PCR (RT-PCR) in 10 samples from each of BE, NE (5 from Barrett's patients and 5 from non-Barrett's patients with a normal oesophagus) and 10 GM samples (collected from the cardia of Barrett's patients, table 2). The cardia was defined as 1 cm below the upper border of the gastric folds at the lower oesophagus in non-Barrett's patients. A frozen section from each snap frozen Barrett's specimen was analyzed by a histopathologist to confirm the presence of IM prior to RNA extraction.

The protein expression of putative biomarkers validated by RT-PCR was confirmed by immunohistochemistry on paraffin embedded section from an independent cohort of 21 non-dysplastic BE, 20 NE, 24 GM and 18 non-inflamed duodenum specimens which were used as a control columnar-lined tissue containing goblet cells (table 2).

TABLE 2 Clinical characteristics of cohorts Age Number of (median M:F Length BE patients [95% CI]) ratio (cm [95% CI]) Real time PCR Normal oesophagus 10 62 [56-59] 1.5:1   Barrett's oesophagus 10 65 [61-68] 2:1 8.3 [6-10]* Gastric mucosa 10 63 [56-69] 1.5:11   Immunohistochemistry Normal oesophagus 20 59 [49-71] 0.8:11   Barrett's oesophagus 21 70 [63-78] 2:1 4.3 [3.2-5.3] Gastric mucosa 24 62 [57-66] 1.5:11  Duodenum 18 58 [24-75] 1:1 Capsule sponge Control patients 99 60 [58-62] 1:1 Known Barrett's 47 64 [60-67] 3:1 6.5 [4.9-7.4] *indicate that the length of the BE samples used for RT-PCR is statistically longer than those for immunohistochemistry (p < 0.01)

RNA Extraction Real-Time PCR

Total RNA from biopsies was extracted by using Trizol (Invitrogen). 1 μg of RNA was reverse transcribed using SuperScript II reverse transcriptase kit (Invitrogen, Paisley, UK) in 20 μL of total reaction solution. The primers used are listed in Table 2. Positive controls were identified for each primer pair using a screen of 25 cells lines from different tissue origins. Quantitative PCR was performed on 2 μL of cDNA with the SYBR Green JumpStart Taq Readymix according to manufacturer's instructions (Sigma-Aldrich, Dorset, UK). PCR consisted of 40 cycles of 94° C. denaturation (15 s), 51-57° C. annealing (30 s; see table 1) and extension (30 s). The cycle threshold Ct was determined for each sample, and the average Ct of triplicate samples was calculated. The expression of each gene relative to Glyceraldehyde-3-Phosphate Dehydrogenase (GAPDH) was determined as ΔCt. A melt curve was constructed for each primer.

Immunohistochemistry

5 μm sections were de-paraffinised in xylene and rehydrated in ethanol. Antigen retrieval was performed in microwave MicroMed T/T Mega (Milestone, Sorisole, Italy) in 0.01 M citrate buffer pH 6.4. The staining procedure was performed using the Dako EnVision™+System. Briefly, non-specific binding was blocked by incubation in 5% BSA in TBS-Tween 0.05% for 1 h and endogenous peroxidises were blocked with the hydrogen peroxide provided with the kit. Tissue sections were incubated with the primary antibody, either mouse anti-TFF3 (R&D Systems Europe Ltd, Abington, UK) or mouse anti-DDC (Protos Biotech Corporation, New York, USA) in 1% BSA in TBS-Tween 0.05% for 1 h at room temperature. The labelled polymer provided with the kit was then applied for 45 min followed by DAB substrate (DakoCytomation Ltd) for 10 min. Sections were counterstained with haematoxylin. A negative control was performed by omission of the primary antibody. Since the capsule sponge samples surface epithelium, quantification of immunohistochemical staining was restricted to the 4 top most layers of the mucosa. A mean of the extent and intensity was generated for each biopsy, reviewed at high magnification (×400), to generate an overall score for each slide. The intensity score was: 0 if absent, 1 for weak, 2 for medium and 3 for strong staining. The extent of staining was scored 1 for focal (1 focus of positive cells), 2 for multifocal (2 or more foci of positive cells) and 3 for extensive (whole biopsy stained) staining.

Analysis

The increased expression in BE compared to NE and GM was first confirmed at the mRNA level by real-time PCR in 10 histopathologically verified endoscopic biopsies from each tissue type. A suitable positive control could not be identified for FUT4 despite evaluating 3 primer pairs across 25 cells lines from different tissues. Validation of this target gene was therefore not taken any further. The expression of DAPK1 and PLCL2 was not statistically different between any groups. Most targets (AGR2, ATP7B, FBP1, FMO5, FOXA3, GOLPH2, LYZ, RNAase4 and TFF1) were statistically increased in BE compared to NE but were similar to GM (FIG. 2). However, both Dopa decarboxylase (DDC) and Trefoil factor 3 (TFF3) were statistically over-expressed in BE compared to NE (p<0.001 and p<0.01 respectively) and GM (p<0.01 and p<0.05 respectively).

Since the capsule sponge specifically samples the uppermost layers of the mucosa, we then went on to validate the expression of TFF3 and DDC in paraffin-embedded section to address the epithelial localization of the antigen. TFF3 was expressed to high levels in BE compared to NE and GM both at the luminal surface and deeper within the tissue (FIGS. 3 and 4, p<0.001). TFF3 was therefore applicable to the capsule sponge which samples the surface layers of the gastric cardia and oesophagus. In contrast, DDC expression was only seen in 4/19 patients with BE and was absent in adjacent tissues (NE or GM) as expected. In the positive BE samples, DDC expression was very weak, limited to a small cluster of cells (less than 8) and localized towards the bottom of the crypts (FIG. 5).

Example 3 TFF3 Expression in Samples Collected with the Capsule Sponge

Since TFF3 fulfilled the necessary criteria, in that expression was restricted to the luminal surface of BE with no expression seen in gastric or normal squamous oesophageal tissues this was taken forward to the prospective capsule sponge screening study. TFF3 expression in specimens from 46 histologically confirmed BE patients were compared to 99 patients without BE.

Capsule Sponge Specimens

Following approval by the Cambridge Local Research Ethics Committee, 29 patients with known long-segment BE and 99 control patients (table 2), whose diagnosis was verified by endoscopy, were recruited. Only patients with a segment≧3 cm were recruited to avoid erroneous diagnoses of hiatus hernia. Control patients were selected on the basis that they had reflux symptoms sufficient to require a prescription of acid-suppressant for a minimum of 3 months over the last 5 years but without diagnosis of BE. The patients were invited to attend a clinic at which they swallowed the sponge with a bolus of water and the capsule was left in place for 5 minutes before retrieval in preservative solution (SurePath, Burlington N.C., USA) as previously described [30].

Processing of the Capsule Sponge Specimens

Samples were left in preservative solution for a minimum of 1 hour. The samples were incubated for 30 minutes in Cytolyt® solution (Cytyc corporation), washed twice in PBS and pelleted at 1000 RPM for 5 minutes. The resulting pellet was re-suspended in 500 μL of plasma and thrombin (Diagnostic reagents, Oxford, UK) was then added in 10 μL increments until a clot formed. The clot was then placed in formalin for 24 h prior to processing into a paraffin block. The entire sample was cut in 5 μm sections to provide 20 slides. The first slide and every tenth slide were stained with H&E. Two sections representative of the whole sample, 10 slides apart, were stained for TFF3 as described above. A slide was scored positive for TFF3 if any cell was stained for TFF3.

Statistical Analysis

A Kruskal-Wallis one-way analysis of variance by ranks was performed to analyse differences in mRNA expression and expression of TFF3 at the luminal surface between the three groups using Prism (GraphPad Software). Specific differences were identified using a Dunn's post test. Microarray analysis was performed as described above.

One sample from a known Barrett's patient had a low cell yield and was excluded from the analysis. The staining was very intense (FIG. 6) and a dichotomous score (staining present or not) was used to maximize specificity. 36 out 46 patients and 6 out of 99 control patients had a capsule sponge specimen positive for TFF3. A sensitivity of 78% (95% CI 64-89), specificity of 94% (95% CI 87-98) and a correct proportion of samples diagnosed of 89% (95% CI 83-94) were obtained.

We have demonstrated identification and use of a clinically relevant biomarker through the use of microarray data and careful validation. The biomarker identified using such an approach may be used in conjunction with the capsule sponge test to provide a cost-effective and acceptable screening test for BE.

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Example 4 BEST2: Evaluation of a Non-Endoscopic Immunocytological Device (Cytosponge) for Barrett's Esophagus Screening via a Case-Control Study and a Screening Trial in Primary Care

Background

Incidence rates of oesophageal adenocarcinoma (AC) have increased 6 fold in the last 30 years [1] and the 5 year survival remains less than 14% [2]. For these reasons, both Cancer Research UK and the Chief Medical Officer have highlighted this disease as a strategic priority and recommended that research should be supported to explore minimally invasive screening tests [3]. The ability to detect BE is a critical screening question because this is the precursor for oesophageal adenocarcinoma. Hitherto the utility of screening for BE has been questionable given the lack of treatment options. However, there has been rapid advancement in technologies such as endoscopic mucosal resection and radiofrequency ablation with randomised controlled trial evidence to support their efficacy [4, 5]. In addition, chemoprevention measures are being evaluated in a large CRUK funded trial (AspECT). Therefore screening-detected cases of BE could potentially be coupled to interventions to prevent AC thus avoiding the need for oesophagectomy which has significant mortality and morbidity [2].

Any screening test needs to be simple, safe, precise, validated and acceptable to the population [6]. The current gold-standard endoscopic diagnosis is invasive, technical and expensive. Development of ultrathin transnasal endoscopy may improve acceptability; however it remains an invasive, expensive test requiring technical expertise [7, 8]. Wireless video capsule endoscopy has a high sensitivity [9]; but is also high-tech, expensive and does not permit tissue sampling. Previous attempts to develop non-endoscopic cytological screening tests, such as balloon cytology have failed [10].

Development of the Cytosponge Test and Pilot Data

We have developed an MHRA approved (CI/2007/0053) non-endoscopic device called a Cytosponge to screen for BE (FIG. 1A). It consists of an expandable, spherical mesh which is attached to a string and contained within a soluble capsule. 3-5 minutes after swallowing, the mesh can be retrieved by pulling on the string. After placing into preservative fluid the specimen is processed for biomarker evaluation (FIG. 1B). In a case:control study the most promising BE biomarkers were an antibody raised against the proliferation marker Mcm2; and a mucin characteristic of the intestinal metaplastic phenotype TFF3 [11, 12]. Protein based assays were chosen for their applicability to routine clinical diagnostic pathology laboratories.

Next we examined the feasibility and acceptability of using the Cytosponge in primary care (www.beststudy.org.uk), [13, 14]. To date 491 patients (mean age, 62 years with a M:F ratio of 0.8:1) with a history of reflux disease have been recruited from 2,602 patients from 11 practices giving an uptake of 18.9% in line with previous primary care endoscopic studies [15, 16]. Only 3/491(<0.01%) were unable to swallow the device and there were no serious adverse events. Cytosponge results were compared with endoscopy as the gold-standard with a compliance of 92%. In this population the prevalence of BE containing specialized intestinal metaplasia was 2.2%, in keeping with other non-UK population data [16-19]. Although not powered to determine accuracy of the test as a primary outcome measure, the Cytosponge test detected BE (TFF3) with a sensitivity and specificity of 90% and 95% respectively. Hence, this pilot study has demonstrated that the Cytosponge is simple and safe enough to be applied to the primary care setting. Further data are required to validate the test and provide robust data on its precision. See FIG. 7.

Biomarkers for Risk Stratification

BE progresses to adenocarcinoma via a metaplasia-dysplasia-adenocarcinoma sequence at a rate of 0.6% per year [20]. Therefore, in order to avoid placing an undue burden on endoscopic surveillance, the ideal screening test should also risk stratify patients according to their likelihood of progressing to AC. This is currently assessed by the histopathological assessment of the degree of dysplasia on biopsies but more objective molecular biomarkers are emerging.

DNA ploidy, p16 and p53 abnormalities are currently the best predictors of cancer progression with a relative risk of up to 38.7 (95% CI 10.8-138.5; p<0.001) [21, 22]. Whilst the assays employed for these analyses are highly technical, image cytometric analysis of ploidy [23, 24] and immunohistochemical detection of p53 abnormalities are promising [25]. In addition, cyclin A and MCM2 detect >90% high grade and adenocarcinoma cases [12, 26]. Since these markers specifically detect epithelial cell surface abnormalities using routine immunohistochemistry they are ideally suited to the Cytosponge. Finally, a panel of 8 methylated genes assayed from paraffin embedded specimens have been validated in a double blind study [27, 28].

Hypothesis

We hypothesise that the Cytosponge test could be used as a clinical screening test in primary care, which when coupled with appropriate biomarkers could also diagnose the degree of dysplasia.

Proposed Design

A screening trial together with a Case:Control study will recruit patients from three different populations in order to determine the performance characteristics of the Cytosponge for diagnosing BE compared with endoscopy, including specificity (from controls) and sensitivity (from cases) and numbers needed to test (from the primary-care based trial). The project design was driven by the need to: a) maximise the information gained with regards to both diagnosis of BE and presence of dysplasia and b) to avoid endoscoping individuals with a negative Cytosponge result who would otherwise not have sought medical care. The design is summarised in FIG. 8.

1. Screening Trial: Primary Care

The primary clinical outcome measure for the screening trial will be histologically confirmed BE.

Setting and Practice Recruitment

2,500 individuals with symptomatic reflux will be identified and invited to swallow the Cytosponge via the East of England (EoE) Primary Care Research Network (PCRN). From the 20% acceptance rate in the BEST pilot study we would require a combined practice population of about 500,000 people, from 55-60 practices which is possible via the EoE PCRN. All interested surgeries will be visited by the study staff to discuss the purpose and logistics of the study including a video of a volunteer swallowing the Cytosponge.

Inclusion and Exclusion Criteria

Individuals 50-70 years of age who have required an anti-reflux prescription for >3 months over the past 5 years will be identified from a search of the electronic drug prescribing data base by the practice staff. Patients who had upper GI endoscopy in the past year, those who are known to have BE and individuals unable to give informed consent will be excluded.

Appointment Process

The subject will provide demographic information which will be entered by the study nurse using a custom-made database accessed via the web. Baseline information will be collected (weight, height, waist:hip ratio) and patients will complete a validated reflux questionnaire [29]. The Cytosponge will be administered by the study nurse. Following the test and whilst still in the surgery the subject will complete baseline psychological measures (see section on QOL).

Patients with a positive test (defined on the basis of any TFF3 positivity) will be invited for an endoscopy within 6 weeks. Any BE visible endoscopically will be confirmed with biopsies for standard histopathological evaluation. Further psychological questionnaire measures will be sent by post at days 7 and 90.

A subgroup of individuals (1500 invited to recruit 1200 over the duration of the study) with a negative Cytosponge test will be offered a repeat test (either 1 or 2 years later) and as in the first screening test individuals testing positive will be endoscoped and psychological questionnaires completed.

2. Case-Control Study Secondary Care

The primary clinical outcome measure for the case-control study will be positive staining for TFF3.

Recruitment

500 individuals with known BE (cases) undergoing surveillance, including those referred for further evaluation and management of high grade dysplasia (HGD) will be recruited. 500 individuals referred by their GP for an endoscopic evaluation of dyspepsia (controls) will also be invited to attend. The timeline of the study is summarized in FIGS. 9A-9C.

Inclusion and Exclusion Criteria

Any patient clinically fit for an endoscopy is eligible to take part. Individuals with dysphagia will be excluded. Patients must be able to provide informed consent.

Appointment Process

Baseline demographic and symptom information will be collected as described from the screening trial. After obtaining informed consent the Cytosponge will be administered by the study nurse prior to their clinically indicated endoscopy. Any newly endoscopically diagnosed BE in the control arms will be biopsied as for the screening trial and these patients will be then be considered as cases. For patients undergoing surveillance, biopsies will be taken according to the Seattle protocol and graded according to the Vienna classification system [30]. Prior to biopsies, an endoscopically directed brushing of Barrett's mucosa will be taken for biomarker evaluation to compare with the Cytosponge specimen as previously described [12, 26]. Psychological questionnaire measures will be obtained at days 0, 7 and 90.

Sample Processing from Screening and Case Control Arms

All Cytosponge specimens will be processed as previously described [11] and evaluated for the Barrett's diagnostic biomarkers (TFF3) using a DAKO autostainer according to GCP standards. Samples will be scored in a binary fashion (positive or negative) as already optimised from the pilot study. A screener will identify areas of interest for the expert GI cytologist (M O'D) to verify.

Patients with a positive result for the Barrett's diagnostic biomarkers will have additional sections cut for risk stratification biomarkers. Mcm2, cyclin A and TP53 can be performed on the DAKO autostainer. The ploidy analysis will be performed using image cytometry [23], (Lovat laboratory) and methylation will be performed using methylation specific PCR [27], (Fitzgerald laboratory). The biomarkers will be scored according to previously optimised protocols [11, 12, 23, 26]. These data will be compared to the degree of dysplasia determined from endoscopic biopsies.

Primary and Secondary Clinical Outcomes from Screening and Case-Control Arms:

Primary Outcome:

-   -   Performance characteristics of the Cytosponge test for         diagnosing BE compared with endoscopy, including specificity         (from controls) and sensitivity (from cases) and numbers needed         to test (from the primary-care based screening trial).

Secondary Outcomes:

-   -   Differential sensitivity of screening BE with high-grade         dysplasia compared to non-dysplastic BE.     -   For patients with BE, (screened and surveillance patients) we         will determine the ability of Cytosponge biomarkers to risk         stratify patients in comparison with dysplasia grade obtained         from endoscopic biopsies.     -   Preliminary data on numbers needed to test to detect one case of         BE after an interval of one and two years following a negative         screen. These data will be key to determining the screening         frequency for future trials.     -   Logistics of high-throughput sample processing and automated         analysis of Cytosponge specimens for use in routine NHS or other         health care settings.     -   Recruitment rates and acceptability in the primary care-trial         will be determined and compared between different         socio-demographic groups.

Potential for Bolt-on Studies and Translational Research:

-   -   Surplus material from screening and surveillance populations         will be used for testing emerging biomarkers     -   Longer term (20 years), the incidence of oesophageal         adenocarcinoma in individuals with positive versus negative test         will be available through flagging with the ECRiC Eastern Cancer         Registry and Information Centre.     -   Opportunity to re-contact participants in the screening trial in         relation to other cancer prevention behavioural interventions         e.g. smoking cessation, obesity reduction or chemoprevention.

Sample Size Estimation:

The main goal is to obtain accurate estimates of the screening parameters (sensitivity, specificity, positive predictive value and numbers needed to screen to detect one case). We therefore aim to estimate specificity with 95% confidence intervals of approximately +/−1% and sensitivity with intervals of +/−2.5%. Where testing has been considered (such as comparing Barrett's with and without high grade dysplasia, or comparing results at entry and 12 or 24 months later) we have aimed for between 80% and 90% power. Details sample size considerations are available from Peter Sasieni on request.

Additional Information on Study Logistics:

A full-time study co-ordinator will be based in Cambridge and work closely with the Cancer Prevention Trials Unit.

1) Screening Trial: Primary Care

Three full-time research nurses based in EoE will work in parallel to recruit participants. The NIHR primary care network is being approached for funding support for research nurses. Twice monthly endoscopy, in primary-care associated units in proximity to the practices concerned, will be performed by a Joint Advisory Board (JAG) accredited upper GI endoscopist. Appointments will be made by a full-time study booking clerk working with the study co-ordinator in Cambridge.

2) Case:Control Study: Secondary Care

The patients will be recruited form 3 tertiary referral centres (Cambridge, Nottingham and UCLH) with expertise in BE (over 700 patients per year of which 135 have HGD). These centres all have research nurses who will have dedicated time for this study (5 sessions per week).

Quality of Life and Economic Evaluations

To measure the impact of screening on psycho-social well-being participants will complete the validated Impact of Events Scale and the Short Form STAI/TRAIT anxiety questionnaires before the test, 7 and 90 days later. Health state utility data using the EQ-5D as recommended by NICE [31]) and resource use data (diagnostic and therapeutic endoscopy, anti-reflux medication, surgery) will be collected. This information will subsequently be used to populate a Markov process model to estimate the cost per QALY from a UK perspective to compare to existing data concerning endoscopic screening for BE [32]. Funding is not required for this part of the proposal. A parallel application will be made to the NIHR to fund quality of life and health economic studies. See FIG. 10.

Data Collection and Analyses

Preparation, staining and reading of slides from the Cytosponge will be done blinded to the route by which the patient was recruited (screening, case, potential control) and to any endoscopy findings. Similarly, BE histology will be evaluated blinded to the reason for endoscopy (surveillance or triage of a positive screen). Interim analyses will be performed at the end of the first and second year of the study.

The data will be analysed using standard techniques for screening studies. In the screening trial adjustments will be made for the lack of endoscopy both in those who screen negative and more particularly in those who screen positive but subsequently fail to comply with recommended follow-up. A detailed statistical analysis plan will be produced in conjunction with PS before the data are examined. Exploratory analyses will explore factors (such as ages, sex and obesity) affecting specificity and disease prevalence in the screening trial.

Clinical Governance

The Cancer Prevention Clinical Trials Unit will ensure clinical governance standards are met and will advise on practical issues. The TFF3 biomarker assays will be performed in clinical histopathological laboratories to GCP standards. All clinical decisions concerning interventions for BE associated dysplasia will be made on the basis of the histopathological grading of the endoscopic biopsies according to standard clinical practice without reference to biomarker data.

An advisory board will meet annually during the course of the study to: oversee and advise, serve as a dissemination vehicle to other researchers and policy makers and to serve as a ‘springboard’ for subsequent epidemiological and clinical collaborations.

Anticipated Use of Study Results to Inform Clinical Decision Making

Increasing public awareness and an increasing incidence of AC mean that it is timely to conduct work to inform policy decisions about a national BE screening programme. In the future the results from this study could lead on to a RCT to compare the effects of screening, coupled with endoscopic treatment for those individuals diagnosed with high risk BE, compared with no screening on mortality form AC.

REFERENCES

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TABLE 1 microarray datasets selected for analysis Specimens Array Reference Normalisation Source of data Hao, 2006³³ 15 Normal Spotted Commercial Intensity- Stanford microarray oesophagus cDNA human dependent database 14 Barrett's array RNA (http://genome-www5.stanford.edu) oesophagus (42,000 spots) Boussioutas, 8 Normal Spotted Pool of 11 LOWESS GEO Accession 2003³⁴ stomach cDNA normal normalisation GSE2669 27 Chronic array gastric gastritis (11,500 specimen 22 Gastric spots) IM Greenawalt, 39 Normal Spotted Pool of 11 LOWESS ArrayExpress ID E- 2007³⁵ oesophagus cDNA cell lines normalisation MEXP-692 26 Barrett's array oesophagus (11,500 spots)

TABLE 2 Clinical characteristics of cohorts Age Number of (median M:F Length BE patients [95% CI]) ratio (cm [95% CI]) Real time PCR Normal oesophagus 10 62 [56-59] 1.5:1   Barrett's oesophagus 10 65 [61-68] 2:1 8.3 [6-10]* Gastric mucosa 10 63 [56-69] 1.5:1   Immunohistochemistry Normal oesophagus 20 59 [49-71] 0.8:1   Barrett's oesophagus 21 70 [63-78] 2:1 4.3 [3.2-5.3] Gastric mucosa 24 62 [57-66] 1.5:1   Duodenum 18 58 [24-75] 1:1 Capsule sponge Control patients 99 60 [58-62] 1:1 Known Barrett's 29 64 [60-67] 3:1 5.7 [4.3-7.1] *indicate that the length of the BE samples used for RT-PCR is statistically longer than those for immunohistochemistry (p < 0.01)

TABLE 3 Putative biomarkers, primer sequences and PCR conditions Accession Forward Reverse Annealing Name Symbol number primer primer T ° C. Anterior gradient 2 AGR2 NM_006408 TTGTCCTCCT GCAGGTTCG 53 CAATCTGGTT TAAGCATAG TATG (SEQ AGAC (SEQ ID NO. 1) ID NO. 2) ATPase, Cu2+ ATP7B NM_000053.2 ACAAAGCACT ATATTCAAGA 53 transporting, β AACCCAAAGA CGCAAGACT polypeptide GAC (SEQ ID TACAATG NO. 3) (SEQ ID NO. 4) Death-associated DAPK1 NM_004938 AACTACGAAT GATCCAGGG 53 protein kinase-1 TTGAGGATGA ATGCTGCAA ATACTTC AC (SEQ ID NO. 5) (SEQ ID NO. 6) M-Dopa DDC NM_000790 CTTCGCCTAC CTTTGGTAGT 55 decarboxylase TTCCCCACTG TCCAGCATC (SEQ ID NO. 7) TTCC (SEQ ID NO. 8) Fructose-1,6- FBP1 NM_000507 CACTGAGTAC CTTCTTGTTA 57 biphosphate ATCCAGAGGA GCGGGGTAC decarboxylase AG (SEQ AG (SEQ ID NO. 9) ID NO. 10) Flavin containing FMO5 NM_001461.1 GGACAGGCG CCTTTCAAAG 53 monooxygenase ACACTAACAGG CAGACAGGT (SEQ ID NO. 11) TCC (SEQ ID NO. 12) Forkhead box A3 FOXA3 NM_004497.2 TGCTGCCTCG AGTGAAATA 56 ACCACCAC GGGTGTGGA (SEQ ID NO. 13) GGAAG (SEQ ID NO. 14) Fucosyltransferase 4 FUT4 NM_002033.2 N/A* N/A* N/A golgi GOLPH2 NM_177937.1 AGTGTGAGGA TGTCTGGGA 53 phosphoprotein 2 GCGAATAGAA CTTGCTGTTA GAG (SEQ CC (SEQ ID NO. 15) ID NO. 16) lysozyme (renal LYZ NM_000239.1 GACCTAGCAG CCATTCCCA 53 amyloidosis) TCAACATGAA ATCTTTTCAG GG (SEQ AGTTC ID NO. 17) (SEQ ID NO. 18) phospholipase C- PLCL2 NM_015184.2 CCATCAAGGA ATATATGACG 56 like 2 AGTGAGAACA GAAAACGCA GG (SEQ CAATC ID NO. 19) (SEQ ID NO. 20) ribonuclease, RNAse4 NM_194430 GCAGAGGAC CGCAGGAAT 57 RNase A family, 4 CCATTCATTGC CGCTGGTAC (SEQ ID NO. 21) (SEQ ID NO. 22) Trefoil factor 1 TFF1 NM_003225 CCCCGTGAAA CGTCGATGG 53 GACAGAATTG TATTAGGATA TG (SEQ GAAGC (SEQ ID NO. 23) ID NO. 24) Trefoil factor 3 TFF3 NM_003226.2 TCTGGGAGCT GGATTGTTT 56 TGACAAAGGC GCTTGGGGA (SEQ ID NO. 25) AGG (SEQ ID NO. 26) *N/A: qPCR analysis was not performed since no suitable positive control could be identified 

The invention claimed is:
 1. A non-invasive method of screening for Barrett's oesophagus (BE) in a subject comprising: obtaining a sample of cells, including oesophageal cells, from a subject using a swallowable device comprising an abrasive material configured to be sufficiently abrasive to collect at least some columnar cells in said sample of cells; and determining the presence of Trefoil factor 3 (TFF3) in said sample of cells, wherein the presence of said TFF3 is indicative of said subject having BE, and wherein the specificity and sensitivity of said method of screening for BE are at least about 80% and about 65% respectively.
 2. The method of claim 1, wherein said cells are a mixed population of cells taken from the cellular surface of the oesophagus.
 3. The method of claim 1, wherein said sample of cells comprise cells from the oesophagus and gastric mucosa cells.
 4. The method of claim 1, wherein said method is non-endoscopic.
 5. The method of claim 1, wherein said subject does not present with BE lesions.
 6. The method of claim 1, wherein said device comprises a capsule sponge.
 7. The method of claim 6 wherein the specificity and sensitivity of said method for diagnosis of BE are about 94% and about 78% respectively.
 8. The method of claim 1 wherein said TFF3 is detected in an immunoassay using an antibody specific for TFF3.
 9. The method of claim 1 wherein the TFF3 is detected using an immunohistochemical detection method.
 10. The method of claim 1 further comprising staining the cells with an Alcian Blue stain to confirm diagnosis of BE.
 11. The method of claim 1 wherein said abrasive material comprises polyurethane.
 12. The method of claim 1 wherein the size and abrasiveness of said material is configured to sample substantially the entire oesophageal lumen of said subject. 